/*
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License version 2 as
 * published by the Free Software Foundation;
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 *
 * Author: Blake Hurd  <naimorai@gmail.com>
 */
#ifdef NS3_OPENFLOW

#include "openflow-switch-net-device.h"

#include "ns3/tcp-l4-protocol.h"
#include "ns3/udp-l4-protocol.h"

namespace ns3
{

NS_LOG_COMPONENT_DEFINE("OpenFlowSwitchNetDevice");

NS_OBJECT_ENSURE_REGISTERED(OpenFlowSwitchNetDevice);

const char*
OpenFlowSwitchNetDevice::GetManufacturerDescription()
{
    return "The ns-3 team";
}

const char*
OpenFlowSwitchNetDevice::GetHardwareDescription()
{
    return "N/A";
}

const char*
OpenFlowSwitchNetDevice::GetSoftwareDescription()
{
    return "Simulated OpenFlow Switch";
}

const char*
OpenFlowSwitchNetDevice::GetSerialNumber()
{
    return "N/A";
}

static uint64_t
GenerateId()
{
    uint8_t ea[ETH_ADDR_LEN];
    eth_addr_random(ea);
    return eth_addr_to_uint64(ea);
}

TypeId
OpenFlowSwitchNetDevice::GetTypeId()
{
    static TypeId tid =
        TypeId("ns3::OpenFlowSwitchNetDevice")
            .SetParent<NetDevice>()
            .SetGroupName("Openflow")
            .AddConstructor<OpenFlowSwitchNetDevice>()
            .AddAttribute("ID",
                          "The identification of the OpenFlowSwitchNetDevice/Datapath, needed for "
                          "OpenFlow compatibility.",
                          UintegerValue(GenerateId()),
                          MakeUintegerAccessor(&OpenFlowSwitchNetDevice::m_id),
                          MakeUintegerChecker<uint64_t>())
            .AddAttribute("FlowTableLookupDelay",
                          "A real switch will have an overhead for looking up in the flow table. "
                          "For the default, we simulate a standard TCAM on an FPGA.",
                          TimeValue(NanoSeconds(30)),
                          MakeTimeAccessor(&OpenFlowSwitchNetDevice::m_lookupDelay),
                          MakeTimeChecker())
            .AddAttribute("Flags", // Note: The Controller can configure this value, overriding the
                                   // user's setting.
                          "Flags to turn different functionality on/off, such as whether to inform "
                          "the controller when a flow expires, or how to handle fragments.",
                          UintegerValue(0), // Look at the ofp_config_flags enum in
                                            // openflow/include/openflow.h for options.
                          MakeUintegerAccessor(&OpenFlowSwitchNetDevice::m_flags),
                          MakeUintegerChecker<uint16_t>())
            .AddAttribute("FlowTableMissSendLength", // Note: The Controller can configure this
                                                     // value, overriding the user's setting.
                          "When forwarding a packet the switch didn't match up to the controller, "
                          "it can be more efficient to forward only the first x bytes.",
                          UintegerValue(OFP_DEFAULT_MISS_SEND_LEN), // 128 bytes
                          MakeUintegerAccessor(&OpenFlowSwitchNetDevice::m_missSendLen),
                          MakeUintegerChecker<uint16_t>());
    return tid;
}

OpenFlowSwitchNetDevice::OpenFlowSwitchNetDevice()
    : m_node(nullptr),
      m_ifIndex(0),
      m_mtu(0xffff)
{
    NS_LOG_FUNCTION_NOARGS();

    m_channel = CreateObject<BridgeChannel>();

    time_init(); // OFSI's clock; needed to use the buffer storage system.
    // m_lastTimeout = time_now ();

    m_controller = nullptr;
    // m_listenPVConn = 0;

    m_chain = chain_create();
    if (!m_chain)
    {
        NS_LOG_ERROR("Not enough memory to create the flow table.");
    }

    m_ports.reserve(DP_MAX_PORTS);
    vport_table_init(&m_vportTable);
}

OpenFlowSwitchNetDevice::~OpenFlowSwitchNetDevice()
{
    NS_LOG_FUNCTION_NOARGS();
}

void
OpenFlowSwitchNetDevice::DoDispose()
{
    NS_LOG_FUNCTION_NOARGS();

    for (Ports_t::iterator b = m_ports.begin(), e = m_ports.end(); b != e; b++)
    {
        SendPortStatus(*b, OFPPR_DELETE);
        b->netdev = nullptr;
    }
    m_ports.clear();

    m_controller = nullptr;

    chain_destroy(m_chain);
    RBTreeDestroy(m_vportTable.table);
    m_channel = nullptr;
    m_node = nullptr;
    NetDevice::DoDispose();
}

void
OpenFlowSwitchNetDevice::SetController(Ptr<ofi::Controller> c)
{
    if (m_controller)
    {
        NS_LOG_ERROR("Controller already set.");
        return;
    }

    m_controller = c;
    m_controller->AddSwitch(this);
}

int
OpenFlowSwitchNetDevice::AddSwitchPort(Ptr<NetDevice> switchPort)
{
    NS_LOG_FUNCTION_NOARGS();
    NS_ASSERT(switchPort != this);
    if (!Mac48Address::IsMatchingType(switchPort->GetAddress()))
    {
        NS_FATAL_ERROR("Device does not support eui 48 addresses: cannot be added to switch.");
    }
    if (!switchPort->SupportsSendFrom())
    {
        NS_FATAL_ERROR("Device does not support SendFrom: cannot be added to switch.");
    }
    if (m_address == Mac48Address())
    {
        m_address = Mac48Address::ConvertFrom(switchPort->GetAddress());
    }

    if (m_ports.size() < DP_MAX_PORTS)
    {
        ofi::Port p;
        p.config = 0;
        p.netdev = switchPort;
        m_ports.push_back(p);

        // Notify the controller that this port has been added
        SendPortStatus(p, OFPPR_ADD);

        NS_LOG_DEBUG("RegisterProtocolHandler for " << switchPort->GetInstanceTypeId().GetName());
        m_node->RegisterProtocolHandler(
            MakeCallback(&OpenFlowSwitchNetDevice::ReceiveFromDevice, this),
            0,
            switchPort,
            true);
        m_channel->AddChannel(switchPort->GetChannel());
    }
    else
    {
        return EXFULL;
    }

    return 0;
}

void
OpenFlowSwitchNetDevice::SetIfIndex(const uint32_t index)
{
    NS_LOG_FUNCTION_NOARGS();
    m_ifIndex = index;
}

uint32_t
OpenFlowSwitchNetDevice::GetIfIndex() const
{
    NS_LOG_FUNCTION_NOARGS();
    return m_ifIndex;
}

Ptr<Channel>
OpenFlowSwitchNetDevice::GetChannel() const
{
    NS_LOG_FUNCTION_NOARGS();
    return m_channel;
}

void
OpenFlowSwitchNetDevice::SetAddress(Address address)
{
    NS_LOG_FUNCTION_NOARGS();
    m_address = Mac48Address::ConvertFrom(address);
}

Address
OpenFlowSwitchNetDevice::GetAddress() const
{
    NS_LOG_FUNCTION_NOARGS();
    return m_address;
}

bool
OpenFlowSwitchNetDevice::SetMtu(const uint16_t mtu)
{
    NS_LOG_FUNCTION_NOARGS();
    m_mtu = mtu;
    return true;
}

uint16_t
OpenFlowSwitchNetDevice::GetMtu() const
{
    NS_LOG_FUNCTION_NOARGS();
    return m_mtu;
}

bool
OpenFlowSwitchNetDevice::IsLinkUp() const
{
    NS_LOG_FUNCTION_NOARGS();
    return true;
}

void
OpenFlowSwitchNetDevice::AddLinkChangeCallback(Callback<void> callback)
{
}

bool
OpenFlowSwitchNetDevice::IsBroadcast() const
{
    NS_LOG_FUNCTION_NOARGS();
    return true;
}

Address
OpenFlowSwitchNetDevice::GetBroadcast() const
{
    NS_LOG_FUNCTION_NOARGS();
    return Mac48Address("ff:ff:ff:ff:ff:ff");
}

bool
OpenFlowSwitchNetDevice::IsMulticast() const
{
    NS_LOG_FUNCTION_NOARGS();
    return true;
}

Address
OpenFlowSwitchNetDevice::GetMulticast(Ipv4Address multicastGroup) const
{
    NS_LOG_FUNCTION(this << multicastGroup);
    Mac48Address multicast = Mac48Address::GetMulticast(multicastGroup);
    return multicast;
}

bool
OpenFlowSwitchNetDevice::IsPointToPoint() const
{
    NS_LOG_FUNCTION_NOARGS();
    return false;
}

bool
OpenFlowSwitchNetDevice::IsBridge() const
{
    NS_LOG_FUNCTION_NOARGS();
    return true;
}

void
OpenFlowSwitchNetDevice::DoOutput(uint32_t packet_uid,
                                  int in_port,
                                  size_t max_len,
                                  int out_port,
                                  bool ignore_no_fwd)
{
    if (out_port != OFPP_CONTROLLER)
    {
        OutputPort(packet_uid, in_port, out_port, ignore_no_fwd);
    }
    else
    {
        OutputControl(packet_uid, in_port, max_len, OFPR_ACTION);
    }
}

bool
OpenFlowSwitchNetDevice::Send(Ptr<Packet> packet, const Address& dest, uint16_t protocolNumber)
{
    NS_LOG_FUNCTION_NOARGS();
    return SendFrom(packet, m_address, dest, protocolNumber);
}

bool
OpenFlowSwitchNetDevice::SendFrom(Ptr<Packet> packet,
                                  const Address& src,
                                  const Address& dest,
                                  uint16_t protocolNumber)
{
    NS_LOG_FUNCTION_NOARGS();

    ofpbuf* buffer = BufferFromPacket(packet, src, dest, GetMtu(), protocolNumber);

    uint32_t packet_uid = save_buffer(buffer);
    ofi::SwitchPacketMetadata data;
    data.packet = packet;
    data.buffer = buffer;
    data.protocolNumber = protocolNumber;
    data.src = Address(src);
    data.dst = Address(dest);
    m_packetData.insert(std::make_pair(packet_uid, data));

    RunThroughFlowTable(packet_uid, -1);

    return true;
}

Ptr<Node>
OpenFlowSwitchNetDevice::GetNode() const
{
    NS_LOG_FUNCTION_NOARGS();
    return m_node;
}

void
OpenFlowSwitchNetDevice::SetNode(Ptr<Node> node)
{
    NS_LOG_FUNCTION_NOARGS();
    m_node = node;
}

bool
OpenFlowSwitchNetDevice::NeedsArp() const
{
    NS_LOG_FUNCTION_NOARGS();
    return true;
}

void
OpenFlowSwitchNetDevice::SetReceiveCallback(NetDevice::ReceiveCallback cb)
{
    NS_LOG_FUNCTION_NOARGS();
    m_rxCallback = cb;
}

void
OpenFlowSwitchNetDevice::SetPromiscReceiveCallback(NetDevice::PromiscReceiveCallback cb)
{
    NS_LOG_FUNCTION_NOARGS();
    m_promiscRxCallback = cb;
}

bool
OpenFlowSwitchNetDevice::SupportsSendFrom() const
{
    NS_LOG_FUNCTION_NOARGS();
    return true;
}

Address
OpenFlowSwitchNetDevice::GetMulticast(Ipv6Address addr) const
{
    NS_LOG_FUNCTION(this << addr);
    return Mac48Address::GetMulticast(addr);
}

// Add a virtual port table entry.
int
OpenFlowSwitchNetDevice::AddVPort(const ofp_vport_mod* ovpm)
{
    size_t actions_len = ntohs(ovpm->header.length) - sizeof *ovpm;
    unsigned int vport = ntohl(ovpm->vport);
    unsigned int parent_port = ntohl(ovpm->parent_port);

    // check whether port table entry exists for specified port number
    vport_table_entry* vpe = vport_table_lookup(&m_vportTable, vport);
    if (vpe)
    {
        NS_LOG_ERROR("vport " << vport << " already exists!");
        SendErrorMsg(OFPET_BAD_ACTION, OFPET_VPORT_MOD_FAILED, ovpm, ntohs(ovpm->header.length));
        return EINVAL;
    }

    // check whether actions are valid
    uint16_t v_code = ofi::ValidateVPortActions(ovpm->actions, actions_len);
    if (v_code != ACT_VALIDATION_OK)
    {
        SendErrorMsg(OFPET_BAD_ACTION, v_code, ovpm, ntohs(ovpm->header.length));
        return EINVAL;
    }

    vpe = vport_table_entry_alloc(actions_len);

    vpe->vport = vport;
    vpe->parent_port = parent_port;
    if (vport < OFPP_VP_START || vport > OFPP_VP_END)
    {
        NS_LOG_ERROR("port " << vport << " is not in the virtual port range (" << OFPP_VP_START
                             << "-" << OFPP_VP_END << ")");
        SendErrorMsg(OFPET_BAD_ACTION, OFPET_VPORT_MOD_FAILED, ovpm, ntohs(ovpm->header.length));
        free_vport_table_entry(vpe); // free allocated entry
        return EINVAL;
    }

    vpe->port_acts->actions_len = actions_len;
    memcpy(vpe->port_acts->actions, ovpm->actions, actions_len);

    int error = insert_vport_table_entry(&m_vportTable, vpe);
    if (error)
    {
        NS_LOG_ERROR("could not insert port table entry for port " << vport);
    }

    return error;
}

ofpbuf*
OpenFlowSwitchNetDevice::BufferFromPacket(Ptr<const Packet> constPacket,
                                          Address src,
                                          Address dst,
                                          int mtu,
                                          uint16_t protocol)
{
    NS_LOG_INFO("Creating Openflow buffer from packet.");

    Ptr<Packet> packet = constPacket->Copy();
    /*
     * Allocate buffer with some headroom to add headers in forwarding
     * to the controller or adding a vlan tag, plus an extra 2 bytes to
     * allow IP headers to be aligned on a 4-byte boundary.
     */
    const int headroom = 128 + 2;
    const int hard_header = VLAN_ETH_HEADER_LEN;
    ofpbuf* buffer = ofpbuf_new(headroom + hard_header + mtu);
    buffer->data = (char*)buffer->data + headroom + hard_header;

    int l2_length = 0;
    int l3_length = 0;
    int l4_length = 0;

    // Parse Ethernet header
    buffer->l2 = new eth_header;
    eth_header* eth_h = (eth_header*)buffer->l2;
    dst.CopyTo(eth_h->eth_dst); // Destination Mac Address
    src.CopyTo(eth_h->eth_src); // Source Mac Address
    if (protocol == ArpL3Protocol::PROT_NUMBER)
    {
        eth_h->eth_type = htons(ETH_TYPE_ARP); // Ether Type
    }
    else if (protocol == Ipv4L3Protocol::PROT_NUMBER)
    {
        eth_h->eth_type = htons(ETH_TYPE_IP); // Ether Type
    }
    else
    {
        NS_LOG_WARN("Protocol unsupported: " << protocol);
    }
    NS_LOG_INFO("Parsed EthernetHeader");

    l2_length = ETH_HEADER_LEN;

    // We have to wrap this because PeekHeader has an assert fail if we check for an Ipv4Header that
    // isn't there.
    if (protocol == Ipv4L3Protocol::PROT_NUMBER)
    {
        Ipv4Header ip_hd;
        if (packet->PeekHeader(ip_hd))
        {
            buffer->l3 = new ip_header;
            ip_header* ip_h = (ip_header*)buffer->l3;
            ip_h->ip_ihl_ver = IP_IHL_VER(5, IP_VERSION); // Version
            ip_h->ip_tos = ip_hd.GetTos();                // Type of Service/Differentiated Services
            ip_h->ip_tot_len = packet->GetSize();         // Total Length
            ip_h->ip_id = ip_hd.GetIdentification();      // Identification
            ip_h->ip_frag_off = ip_hd.GetFragmentOffset();      // Fragment Offset
            ip_h->ip_ttl = ip_hd.GetTtl();                      // Time to Live
            ip_h->ip_proto = ip_hd.GetProtocol();               // Protocol
            ip_h->ip_src = htonl(ip_hd.GetSource().Get());      // Source Address
            ip_h->ip_dst = htonl(ip_hd.GetDestination().Get()); // Destination Address
            ip_h->ip_csum = csum(&ip_h, sizeof ip_h);           // Header Checksum
            NS_LOG_INFO("Parsed Ipv4Header");
            packet->RemoveHeader(ip_hd);

            l3_length = IP_HEADER_LEN;
        }
    }
    else
    {
        // ARP Packet; the underlying OpenFlow header isn't used to match, so this is probably
        // superfluous.
        ArpHeader arp_hd;
        if (packet->PeekHeader(arp_hd))
        {
            buffer->l3 = new arp_eth_header;
            arp_eth_header* arp_h = (arp_eth_header*)buffer->l3;
            arp_h->ar_hrd = ARP_HRD_ETHERNET; // Hardware type.
            arp_h->ar_pro = ARP_PRO_IP;       // Protocol type.
            arp_h->ar_op = arp_hd.m_type;     // Opcode.
            arp_hd.GetDestinationHardwareAddress().CopyTo(
                arp_h->ar_tha);                                       // Target hardware address.
            arp_hd.GetSourceHardwareAddress().CopyTo(arp_h->ar_sha);  // Sender hardware address.
            arp_h->ar_tpa = arp_hd.GetDestinationIpv4Address().Get(); // Target protocol address.
            arp_h->ar_spa = arp_hd.GetSourceIpv4Address().Get();      // Sender protocol address.
            arp_h->ar_hln = sizeof arp_h->ar_tha;                     // Hardware address length.
            arp_h->ar_pln = sizeof arp_h->ar_tpa;                     // Protocol address length.
            NS_LOG_INFO("Parsed ArpHeader");
            packet->RemoveHeader(arp_hd);

            l3_length = ARP_ETH_HEADER_LEN;
        }
    }

    if (protocol == Ipv4L3Protocol::PROT_NUMBER)
    {
        ip_header* ip_h = (ip_header*)buffer->l3;
        if (ip_h->ip_proto == TcpL4Protocol::PROT_NUMBER)
        {
            TcpHeader tcp_hd;
            if (packet->PeekHeader(tcp_hd))
            {
                buffer->l4 = new tcp_header;
                tcp_header* tcp_h = (tcp_header*)buffer->l4;
                tcp_h->tcp_src = htons(tcp_hd.GetSourcePort());         // Source Port
                tcp_h->tcp_dst = htons(tcp_hd.GetDestinationPort());    // Destination Port
                tcp_h->tcp_seq = tcp_hd.GetSequenceNumber().GetValue(); // Sequence Number
                tcp_h->tcp_ack = tcp_hd.GetAckNumber().GetValue();      // ACK Number
                tcp_h->tcp_ctl = TCP_FLAGS(tcp_hd.GetFlags()); // Data Offset + Reserved + Flags
                tcp_h->tcp_winsz = tcp_hd.GetWindowSize();     // Window Size
                tcp_h->tcp_urg = tcp_hd.GetUrgentPointer();    // Urgent Pointer
                tcp_h->tcp_csum = csum(&tcp_h, sizeof tcp_h);  // Header Checksum
                NS_LOG_INFO("Parsed TcpHeader");
                packet->RemoveHeader(tcp_hd);

                l4_length = TCP_HEADER_LEN;
            }
        }
        else if (ip_h->ip_proto == UdpL4Protocol::PROT_NUMBER)
        {
            UdpHeader udp_hd;
            if (packet->PeekHeader(udp_hd))
            {
                buffer->l4 = new udp_header;
                udp_header* udp_h = (udp_header*)buffer->l4;
                udp_h->udp_src = htons(udp_hd.GetSourcePort());      // Source Port
                udp_h->udp_dst = htons(udp_hd.GetDestinationPort()); // Destination Port
                udp_h->udp_len = htons(UDP_HEADER_LEN + packet->GetSize());

                ip_header* ip_h = (ip_header*)buffer->l3;
                uint32_t udp_csum = csum_add32(0, ip_h->ip_src);
                udp_csum = csum_add32(udp_csum, ip_h->ip_dst);
                udp_csum = csum_add16(udp_csum, IP_TYPE_UDP << 8);
                udp_csum = csum_add16(udp_csum, udp_h->udp_len);
                udp_csum = csum_continue(udp_csum, udp_h, sizeof udp_h);
                udp_h->udp_csum = csum_finish(
                    csum_continue(udp_csum, buffer->data, buffer->size)); // Header Checksum
                NS_LOG_INFO("Parsed UdpHeader");
                packet->RemoveHeader(udp_hd);

                l4_length = UDP_HEADER_LEN;
            }
        }
    }

    // Load any remaining packet data into buffer data
    packet->CopyData((uint8_t*)buffer->data, packet->GetSize());

    if (buffer->l4)
    {
        ofpbuf_push(buffer, buffer->l4, l4_length);
        delete (tcp_header*)buffer->l4;
    }
    if (buffer->l3)
    {
        ofpbuf_push(buffer, buffer->l3, l3_length);
        delete (ip_header*)buffer->l3;
    }
    if (buffer->l2)
    {
        ofpbuf_push(buffer, buffer->l2, l2_length);
        delete (eth_header*)buffer->l2;
    }

    return buffer;
}

void
OpenFlowSwitchNetDevice::ReceiveFromDevice(Ptr<NetDevice> netdev,
                                           Ptr<const Packet> packet,
                                           uint16_t protocol,
                                           const Address& src,
                                           const Address& dst,
                                           PacketType packetType)
{
    NS_LOG_FUNCTION_NOARGS();
    NS_LOG_INFO("--------------------------------------------");
    NS_LOG_DEBUG("UID is " << packet->GetUid());

    if (!m_promiscRxCallback.IsNull())
    {
        m_promiscRxCallback(this, packet, protocol, src, dst, packetType);
    }

    Mac48Address dst48 = Mac48Address::ConvertFrom(dst);
    NS_LOG_INFO("Received packet from " << Mac48Address::ConvertFrom(src) << " looking for "
                                        << dst48);

    for (size_t i = 0; i < m_ports.size(); i++)
    {
        if (m_ports[i].netdev == netdev)
        {
            if (packetType == PACKET_HOST && dst48 == m_address)
            {
                m_rxCallback(this, packet, protocol, src);
            }
            else if (packetType == PACKET_BROADCAST || packetType == PACKET_MULTICAST ||
                     packetType == PACKET_OTHERHOST)
            {
                if (packetType == PACKET_OTHERHOST && dst48 == m_address)
                {
                    m_rxCallback(this, packet, protocol, src);
                }
                else
                {
                    if (packetType != PACKET_OTHERHOST)
                    {
                        m_rxCallback(this, packet, protocol, src);
                    }

                    ofi::SwitchPacketMetadata data;
                    data.packet = packet->Copy();

                    ofpbuf* buffer =
                        BufferFromPacket(data.packet, src, dst, netdev->GetMtu(), protocol);
                    m_ports[i].rx_packets++;
                    m_ports[i].rx_bytes += buffer->size;
                    data.buffer = buffer;
                    uint32_t packet_uid = save_buffer(buffer);

                    data.protocolNumber = protocol;
                    data.src = Address(src);
                    data.dst = Address(dst);
                    m_packetData.insert(std::make_pair(packet_uid, data));

                    RunThroughFlowTable(packet_uid, i);
                }
            }

            break;
        }
    }

    // Run periodic execution.
    Time now = Simulator::Now();
    if (now >= Seconds(m_lastExecute.GetSeconds() +
                       1)) // If a second or more has passed from the simulation time, execute.
    {
        // If port status is modified in any way, notify the controller.
        for (size_t i = 0; i < m_ports.size(); i++)
        {
            if (UpdatePortStatus(m_ports[i]))
            {
                SendPortStatus(m_ports[i], OFPPR_MODIFY);
            }
        }

        // If any flows have expired, delete them and notify the controller.
        List deleted = LIST_INITIALIZER(&deleted);
        sw_flow* f;
        sw_flow* n;
        chain_timeout(m_chain, &deleted);
        LIST_FOR_EACH_SAFE(f, n, sw_flow, node, &deleted)
        {
            std::ostringstream str;
            str << "Flow [";
            for (int i = 0; i < 6; i++)
            {
                str << (i != 0 ? ":" : "") << std::hex << f->key.flow.dl_src[i] / 16
                    << f->key.flow.dl_src[i] % 16;
            }
            str << " -> ";
            for (int i = 0; i < 6; i++)
            {
                str << (i != 0 ? ":" : "") << std::hex << f->key.flow.dl_dst[i] / 16
                    << f->key.flow.dl_dst[i] % 16;
            }
            str << "] expired.";

            NS_LOG_INFO(str.str());
            SendFlowExpired(f, (ofp_flow_expired_reason)f->reason);
            list_remove(&f->node);
            flow_free(f);
        }

        m_lastExecute = now;
    }
}

int
OpenFlowSwitchNetDevice::OutputAll(uint32_t packet_uid, int in_port, bool flood)
{
    NS_LOG_FUNCTION_NOARGS();
    NS_LOG_INFO("Flooding over ports.");

    int prev_port = -1;
    for (size_t i = 0; i < m_ports.size(); i++)
    {
        if (i == (unsigned)in_port) // Originating port
        {
            continue;
        }
        if (flood && m_ports[i].config & OFPPC_NO_FLOOD) // Port configured to not allow flooding
        {
            continue;
        }
        if (prev_port != -1)
        {
            OutputPort(packet_uid, in_port, prev_port, false);
        }
        prev_port = i;
    }
    if (prev_port != -1)
    {
        OutputPort(packet_uid, in_port, prev_port, false);
    }

    return 0;
}

void
OpenFlowSwitchNetDevice::OutputPacket(uint32_t packet_uid, int out_port)
{
    if (out_port >= 0 && out_port < DP_MAX_PORTS)
    {
        ofi::Port& p = m_ports[out_port];
        if (p.netdev && !(p.config & OFPPC_PORT_DOWN))
        {
            ofi::SwitchPacketMetadata data = m_packetData.find(packet_uid)->second;
            size_t bufsize = data.buffer->size;
            NS_LOG_INFO("Sending packet " << data.packet->GetUid() << " over port " << out_port);
            if (p.netdev->SendFrom(data.packet->Copy(), data.src, data.dst, data.protocolNumber))
            {
                p.tx_packets++;
                p.tx_bytes += bufsize;
            }
            else
            {
                p.tx_dropped++;
            }
            return;
        }
    }

    NS_LOG_DEBUG("can't forward to bad port " << out_port);
}

void
OpenFlowSwitchNetDevice::OutputPort(uint32_t packet_uid,
                                    int in_port,
                                    int out_port,
                                    bool ignore_no_fwd)
{
    NS_LOG_FUNCTION_NOARGS();

    if (out_port == OFPP_FLOOD)
    {
        OutputAll(packet_uid, in_port, true);
    }
    else if (out_port == OFPP_ALL)
    {
        OutputAll(packet_uid, in_port, false);
    }
    else if (out_port == OFPP_CONTROLLER)
    {
        OutputControl(packet_uid, in_port, 0, OFPR_ACTION);
    }
    else if (out_port == OFPP_IN_PORT)
    {
        OutputPacket(packet_uid, in_port);
    }
    else if (out_port == OFPP_TABLE)
    {
        RunThroughFlowTable(packet_uid, in_port < DP_MAX_PORTS ? in_port : -1, false);
    }
    else if (out_port >= OFPP_VP_START && out_port <= OFPP_VP_END)
    {
        // port is a virtual port
        NS_LOG_INFO("packet sent to virtual port " << out_port);
        if (in_port < DP_MAX_PORTS)
        {
            RunThroughVPortTable(packet_uid, in_port, out_port);
        }
        else
        {
            RunThroughVPortTable(packet_uid, -1, out_port);
        }
    }
    else if (in_port == out_port)
    {
        NS_LOG_DEBUG("can't directly forward to input port");
    }
    else
    {
        OutputPacket(packet_uid, out_port);
    }
}

void*
OpenFlowSwitchNetDevice::MakeOpenflowReply(size_t openflow_len, uint8_t type, ofpbuf** bufferp)
{
    return make_openflow_xid(openflow_len, type, 0, bufferp);
}

int
OpenFlowSwitchNetDevice::SendOpenflowBuffer(ofpbuf* buffer)
{
    if (m_controller)
    {
        update_openflow_length(buffer);
        m_controller->ReceiveFromSwitch(this, buffer);
    }

    return 0;
}

void
OpenFlowSwitchNetDevice::OutputControl(uint32_t packet_uid, int in_port, size_t max_len, int reason)
{
    NS_LOG_INFO("Sending packet to controller");

    ofpbuf* buffer = m_packetData.find(packet_uid)->second.buffer;
    size_t total_len = buffer->size;
    if (packet_uid != std::numeric_limits<uint32_t>::max() && max_len != 0 &&
        buffer->size > max_len)
    {
        buffer->size = max_len;
    }

    ofp_packet_in* opi = (ofp_packet_in*)ofpbuf_push_uninit(buffer, offsetof(ofp_packet_in, data));
    opi->header.version = OFP_VERSION;
    opi->header.type = OFPT_PACKET_IN;
    opi->header.length = htons(buffer->size);
    opi->header.xid = htonl(0);
    opi->buffer_id = htonl(packet_uid);
    opi->total_len = htons(total_len);
    opi->in_port = htons(in_port);
    opi->reason = reason;
    opi->pad = 0;
    SendOpenflowBuffer(buffer);
}

void
OpenFlowSwitchNetDevice::FillPortDesc(ofi::Port p, ofp_phy_port* desc)
{
    desc->port_no = htons(GetSwitchPortIndex(p));

    std::ostringstream nm;
    nm << "eth" << GetSwitchPortIndex(p);
    strncpy((char*)desc->name, nm.str().c_str(), sizeof desc->name);

    p.netdev->GetAddress().CopyTo(desc->hw_addr);
    desc->config = htonl(p.config);
    desc->state = htonl(p.state);

    /// \todo This should probably be fixed eventually to specify different available features.
    desc->curr = 0;       // htonl(netdev_get_features(p->netdev, NETDEV_FEAT_CURRENT));
    desc->supported = 0;  // htonl(netdev_get_features(p->netdev, NETDEV_FEAT_SUPPORTED));
    desc->advertised = 0; // htonl(netdev_get_features(p->netdev, NETDEV_FEAT_ADVERTISED));
    desc->peer = 0;       // htonl(netdev_get_features(p->netdev, NETDEV_FEAT_PEER));
}

void
OpenFlowSwitchNetDevice::SendFeaturesReply()
{
    ofpbuf* buffer;
    ofp_switch_features* ofr =
        (ofp_switch_features*)MakeOpenflowReply(sizeof *ofr, OFPT_FEATURES_REPLY, &buffer);
    ofr->datapath_id = htonll(m_id);
    ofr->n_tables = m_chain->n_tables;
    ofr->n_buffers = htonl(N_PKT_BUFFERS);
    ofr->capabilities = htonl(OFP_SUPPORTED_CAPABILITIES);
    ofr->actions = htonl(OFP_SUPPORTED_ACTIONS);

    for (size_t i = 0; i < m_ports.size(); i++)
    {
        ofp_phy_port* opp = (ofp_phy_port*)ofpbuf_put_zeros(buffer, sizeof *opp);
        FillPortDesc(m_ports[i], opp);
    }

    SendOpenflowBuffer(buffer);
}

void
OpenFlowSwitchNetDevice::SendVPortTableFeatures()
{
    ofpbuf* buffer;
    ofp_vport_table_features* ovtfr =
        (ofp_vport_table_features*)MakeOpenflowReply(sizeof *ovtfr,
                                                     OFPT_VPORT_TABLE_FEATURES_REPLY,
                                                     &buffer);
    ovtfr->actions = htonl(OFP_SUPPORTED_VPORT_TABLE_ACTIONS);
    ovtfr->max_vports = htonl(m_vportTable.max_vports);
    ovtfr->max_chain_depth = htons(-1); // support a chain depth of 2^16
    ovtfr->mixed_chaining = true;
    SendOpenflowBuffer(buffer);
}

int
OpenFlowSwitchNetDevice::UpdatePortStatus(ofi::Port& p)
{
    uint32_t orig_config = p.config;
    uint32_t orig_state = p.state;

    // Port is always enabled because the Net Device is always enabled.
    p.config &= ~OFPPC_PORT_DOWN;

    if (p.netdev->IsLinkUp())
    {
        p.state &= ~OFPPS_LINK_DOWN;
    }
    else
    {
        p.state |= OFPPS_LINK_DOWN;
    }

    return ((orig_config != p.config) || (orig_state != p.state));
}

void
OpenFlowSwitchNetDevice::SendPortStatus(ofi::Port p, uint8_t status)
{
    ofpbuf* buffer;
    ofp_port_status* ops =
        (ofp_port_status*)MakeOpenflowReply(sizeof *ops, OFPT_PORT_STATUS, &buffer);
    ops->reason = status;
    memset(ops->pad, 0, sizeof ops->pad);
    FillPortDesc(p, &ops->desc);

    SendOpenflowBuffer(buffer);
    ofpbuf_delete(buffer);
}

void
OpenFlowSwitchNetDevice::SendFlowExpired(sw_flow* flow, ofp_flow_expired_reason reason)
{
    ofpbuf* buffer;
    ofp_flow_expired* ofe =
        (ofp_flow_expired*)MakeOpenflowReply(sizeof *ofe, OFPT_FLOW_EXPIRED, &buffer);
    flow_fill_match(&ofe->match, &flow->key);

    ofe->priority = htons(flow->priority);
    ofe->reason = reason;
    memset(ofe->pad, 0, sizeof ofe->pad);

    ofe->duration = htonl(time_now() - flow->created);
    memset(ofe->pad2, 0, sizeof ofe->pad2);
    ofe->packet_count = htonll(flow->packet_count);
    ofe->byte_count = htonll(flow->byte_count);
    SendOpenflowBuffer(buffer);
}

void
OpenFlowSwitchNetDevice::SendErrorMsg(uint16_t type, uint16_t code, const void* data, size_t len)
{
    ofpbuf* buffer;
    ofp_error_msg* oem = (ofp_error_msg*)MakeOpenflowReply(sizeof(*oem) + len, OFPT_ERROR, &buffer);
    oem->type = htons(type);
    oem->code = htons(code);
    memcpy(oem->data, data, len);
    SendOpenflowBuffer(buffer);
}

void
OpenFlowSwitchNetDevice::FlowTableLookup(sw_flow_key key,
                                         ofpbuf* buffer,
                                         uint32_t packet_uid,
                                         int port,
                                         bool send_to_controller)
{
    sw_flow* flow = chain_lookup(m_chain, &key);
    if (flow)
    {
        NS_LOG_INFO("Flow matched");
        flow_used(flow, buffer);
        ofi::ExecuteActions(this,
                            packet_uid,
                            buffer,
                            &key,
                            flow->sf_acts->actions,
                            flow->sf_acts->actions_len,
                            false);
    }
    else
    {
        NS_LOG_INFO("Flow not matched.");

        if (send_to_controller)
        {
            OutputControl(packet_uid, port, m_missSendLen, OFPR_NO_MATCH);
        }
    }

    // Clean up; at this point we're done with the packet.
    m_packetData.erase(packet_uid);
    discard_buffer(packet_uid);
    ofpbuf_delete(buffer);
}

void
OpenFlowSwitchNetDevice::RunThroughFlowTable(uint32_t packet_uid, int port, bool send_to_controller)
{
    ofi::SwitchPacketMetadata data = m_packetData.find(packet_uid)->second;
    ofpbuf* buffer = data.buffer;

    sw_flow_key key;
    key.wildcards = 0; // Lookup cannot take wildcards.
    // Extract the matching key's flow data from the packet's headers; if the policy is to drop
    // fragments and the message is a fragment, drop it.
    if (flow_extract(buffer, port != -1 ? port : OFPP_NONE, &key.flow) &&
        (m_flags & OFPC_FRAG_MASK) == OFPC_FRAG_DROP)
    {
        ofpbuf_delete(buffer);
        return;
    }

    // drop MPLS packets with TTL 1
    if (buffer->l2_5)
    {
        mpls_header mpls_h;
        mpls_h.value = ntohl(*((uint32_t*)buffer->l2_5));
        if (mpls_h.ttl == 1)
        {
            // increment mpls drop counter
            if (port != -1)
            {
                m_ports[port].mpls_ttl0_dropped++;
            }
            return;
        }
    }

    // If we received the packet on a port, and opted not to receive any messages from it...
    if (port != -1)
    {
        uint32_t config = m_ports[port].config;
        if (config & (OFPPC_NO_RECV | OFPPC_NO_RECV_STP) &&
            config & (!eth_addr_equals(key.flow.dl_dst, stp_eth_addr) ? OFPPC_NO_RECV
                                                                      : OFPPC_NO_RECV_STP))
        {
            return;
        }
    }

    NS_LOG_INFO("Matching against the flow table.");
    Simulator::Schedule(m_lookupDelay,
                        &OpenFlowSwitchNetDevice::FlowTableLookup,
                        this,
                        key,
                        buffer,
                        packet_uid,
                        port,
                        send_to_controller);
}

int
OpenFlowSwitchNetDevice::RunThroughVPortTable(uint32_t packet_uid, int port, uint32_t vport)
{
    ofpbuf* buffer = m_packetData.find(packet_uid)->second.buffer;

    // extract the flow again since we need it
    // and the layer pointers may changed
    sw_flow_key key;
    key.wildcards = 0;
    if (flow_extract(buffer, port != -1 ? port : OFPP_NONE, &key.flow) &&
        (m_flags & OFPC_FRAG_MASK) == OFPC_FRAG_DROP)
    {
        return 0;
    }

    // run through the chain of port table entries
    vport_table_entry* vpe = vport_table_lookup(&m_vportTable, vport);
    m_vportTable.lookup_count++;
    if (vpe)
    {
        m_vportTable.port_match_count++;
    }
    while (vpe)
    {
        ofi::ExecuteVPortActions(this,
                                 packet_uid,
                                 m_packetData.find(packet_uid)->second.buffer,
                                 &key,
                                 vpe->port_acts->actions,
                                 vpe->port_acts->actions_len);
        vport_used(vpe, buffer); // update counters for virtual port
        if (!vpe->parent_port_ptr)
        {
            // if a port table's parent_port_ptr is 0 then
            // the parent_port should be a physical port
            if (vpe->parent_port <=
                OFPP_VP_START) // done traversing port chain, send packet to output port
            {
                OutputPort(packet_uid, port != -1 ? port : OFPP_NONE, vpe->parent_port, false);
            }
            else
            {
                NS_LOG_ERROR("virtual port points to parent port\n");
            }
        }
        else // increment the number of port entries accessed by chaining
        {
            m_vportTable.chain_match_count++;
        }
        // move to the parent port entry
        vpe = vpe->parent_port_ptr;
    }

    return 0;
}

int
OpenFlowSwitchNetDevice::ReceiveFeaturesRequest(const void* msg)
{
    SendFeaturesReply();
    return 0;
}

int
OpenFlowSwitchNetDevice::ReceiveVPortTableFeaturesRequest(const void* msg)
{
    SendVPortTableFeatures();
    return 0;
}

int
OpenFlowSwitchNetDevice::ReceiveGetConfigRequest(const void* msg)
{
    ofpbuf* buffer;
    ofp_switch_config* osc =
        (ofp_switch_config*)MakeOpenflowReply(sizeof *osc, OFPT_GET_CONFIG_REPLY, &buffer);
    osc->flags = htons(m_flags);
    osc->miss_send_len = htons(m_missSendLen);

    return SendOpenflowBuffer(buffer);
}

int
OpenFlowSwitchNetDevice::ReceiveSetConfig(const void* msg)
{
    const ofp_switch_config* osc = (ofp_switch_config*)msg;

    int n_flags = ntohs(osc->flags) & (OFPC_SEND_FLOW_EXP | OFPC_FRAG_MASK);
    if ((n_flags & OFPC_FRAG_MASK) != OFPC_FRAG_NORMAL &&
        (n_flags & OFPC_FRAG_MASK) != OFPC_FRAG_DROP)
    {
        n_flags = (n_flags & ~OFPC_FRAG_MASK) | OFPC_FRAG_DROP;
    }

    m_flags = n_flags;
    m_missSendLen = ntohs(osc->miss_send_len);
    return 0;
}

int
OpenFlowSwitchNetDevice::ReceivePacketOut(const void* msg)
{
    const ofp_packet_out* opo = (ofp_packet_out*)msg;
    ofpbuf* buffer;
    size_t actions_len = ntohs(opo->actions_len);

    if (actions_len > (ntohs(opo->header.length) - sizeof *opo))
    {
        NS_LOG_DEBUG("message too short for number of actions");
        return -EINVAL;
    }

    if (ntohl(opo->buffer_id) == (uint32_t)-1)
    {
        // FIXME: can we avoid copying data here?
        int data_len = ntohs(opo->header.length) - sizeof *opo - actions_len;
        buffer = ofpbuf_new(data_len);
        ofpbuf_put(buffer, (uint8_t*)opo->actions + actions_len, data_len);
    }
    else
    {
        buffer = retrieve_buffer(ntohl(opo->buffer_id));
        if (!buffer)
        {
            return -ESRCH;
        }
    }

    sw_flow_key key;
    flow_extract(buffer, ntohs(opo->in_port), &key.flow); // ntohs(opo->in_port)

    uint16_t v_code = ofi::ValidateActions(&key, opo->actions, actions_len);
    if (v_code != ACT_VALIDATION_OK)
    {
        SendErrorMsg(OFPET_BAD_ACTION, v_code, msg, ntohs(opo->header.length));
        ofpbuf_delete(buffer);
        return -EINVAL;
    }

    ofi::ExecuteActions(this, opo->buffer_id, buffer, &key, opo->actions, actions_len, true);
    return 0;
}

int
OpenFlowSwitchNetDevice::ReceivePortMod(const void* msg)
{
    ofp_port_mod* opm = (ofp_port_mod*)msg;

    int port = opm->port_no; // ntohs(opm->port_no);
    if (port < DP_MAX_PORTS)
    {
        ofi::Port& p = m_ports[port];

        // Make sure the port id hasn't changed since this was sent
        Mac48Address hw_addr = Mac48Address();
        hw_addr.CopyFrom(opm->hw_addr);
        if (p.netdev->GetAddress() != hw_addr)
        {
            return 0;
        }

        if (opm->mask)
        {
            uint32_t config_mask = ntohl(opm->mask);
            p.config &= ~config_mask;
            p.config |= ntohl(opm->config) & config_mask;
        }

        if (opm->mask & htonl(OFPPC_PORT_DOWN))
        {
            if ((opm->config & htonl(OFPPC_PORT_DOWN)) && (p.config & OFPPC_PORT_DOWN) == 0)
            {
                p.config |= OFPPC_PORT_DOWN;
                /// \todo Possibly disable the Port's Net Device via the appropriate interface.
            }
            else if ((opm->config & htonl(OFPPC_PORT_DOWN)) == 0 && (p.config & OFPPC_PORT_DOWN))
            {
                p.config &= ~OFPPC_PORT_DOWN;
                /// \todo Possibly enable the Port's Net Device via the appropriate interface.
            }
        }
    }

    return 0;
}

// add or remove a virtual port table entry
int
OpenFlowSwitchNetDevice::ReceiveVPortMod(const void* msg)
{
    const ofp_vport_mod* ovpm = (ofp_vport_mod*)msg;

    uint16_t command = ntohs(ovpm->command);
    if (command == OFPVP_ADD)
    {
        return AddVPort(ovpm);
    }
    else if (command == OFPVP_DELETE)
    {
        if (remove_vport_table_entry(&m_vportTable, ntohl(ovpm->vport)))
        {
            SendErrorMsg(OFPET_BAD_ACTION,
                         OFPET_VPORT_MOD_FAILED,
                         ovpm,
                         ntohs(ovpm->header.length));
        }
    }

    return 0;
}

int
OpenFlowSwitchNetDevice::AddFlow(const ofp_flow_mod* ofm)
{
    size_t actions_len = ntohs(ofm->header.length) - sizeof *ofm;

    // Allocate memory.
    sw_flow* flow = flow_alloc(actions_len);
    if (!flow)
    {
        if (ntohl(ofm->buffer_id) != (uint32_t)-1)
        {
            discard_buffer(ntohl(ofm->buffer_id));
        }
        return -ENOMEM;
    }

    flow_extract_match(&flow->key, &ofm->match);

    uint16_t v_code = ofi::ValidateActions(&flow->key, ofm->actions, actions_len);
    if (v_code != ACT_VALIDATION_OK)
    {
        SendErrorMsg(OFPET_BAD_ACTION, v_code, ofm, ntohs(ofm->header.length));
        flow_free(flow);
        if (ntohl(ofm->buffer_id) != (uint32_t)-1)
        {
            discard_buffer(ntohl(ofm->buffer_id));
        }
        return -ENOMEM;
    }

    // Fill out flow.
    flow->priority = flow->key.wildcards ? ntohs(ofm->priority) : -1;
    flow->idle_timeout = ntohs(ofm->idle_timeout);
    flow->hard_timeout = ntohs(ofm->hard_timeout);
    flow->used = flow->created = time_now();
    flow->sf_acts->actions_len = actions_len;
    flow->byte_count = 0;
    flow->packet_count = 0;
    memcpy(flow->sf_acts->actions, ofm->actions, actions_len);

    // Act.
    int error = chain_insert(m_chain, flow);
    if (error)
    {
        if (error == -ENOBUFS)
        {
            SendErrorMsg(OFPET_FLOW_MOD_FAILED,
                         OFPFMFC_ALL_TABLES_FULL,
                         ofm,
                         ntohs(ofm->header.length));
        }
        flow_free(flow);
        if (ntohl(ofm->buffer_id) != (uint32_t)-1)
        {
            discard_buffer(ntohl(ofm->buffer_id));
        }
        return error;
    }

    NS_LOG_INFO("Added new flow.");
    if (ntohl(ofm->buffer_id) != std::numeric_limits<uint32_t>::max())
    {
        ofpbuf* buffer = retrieve_buffer(ofm->buffer_id); // ntohl(ofm->buffer_id)
        if (buffer)
        {
            sw_flow_key key;
            flow_used(flow, buffer);
            flow_extract(buffer,
                         ntohs(ofm->match.in_port),
                         &key.flow); // ntohs(ofm->match.in_port);
            ofi::ExecuteActions(this,
                                ofm->buffer_id,
                                buffer,
                                &key,
                                ofm->actions,
                                actions_len,
                                false);
            ofpbuf_delete(buffer);
        }
        else
        {
            return -ESRCH;
        }
    }
    return 0;
}

int
OpenFlowSwitchNetDevice::ModFlow(const ofp_flow_mod* ofm)
{
    sw_flow_key key;
    flow_extract_match(&key, &ofm->match);

    size_t actions_len = ntohs(ofm->header.length) - sizeof *ofm;

    uint16_t v_code = ofi::ValidateActions(&key, ofm->actions, actions_len);
    if (v_code != ACT_VALIDATION_OK)
    {
        SendErrorMsg((ofp_error_type)OFPET_BAD_ACTION, v_code, ofm, ntohs(ofm->header.length));
        if (ntohl(ofm->buffer_id) != (uint32_t)-1)
        {
            discard_buffer(ntohl(ofm->buffer_id));
        }
        return -ENOMEM;
    }

    uint16_t priority = key.wildcards ? ntohs(ofm->priority) : -1;
    int strict = (ofm->command == htons(OFPFC_MODIFY_STRICT)) ? 1 : 0;
    chain_modify(m_chain, &key, priority, strict, ofm->actions, actions_len);

    if (ntohl(ofm->buffer_id) != std::numeric_limits<uint32_t>::max())
    {
        ofpbuf* buffer = retrieve_buffer(ofm->buffer_id); // ntohl (ofm->buffer_id)
        if (buffer)
        {
            sw_flow_key skb_key;
            flow_extract(buffer,
                         ntohs(ofm->match.in_port),
                         &skb_key.flow); // ntohs(ofm->match.in_port);
            ofi::ExecuteActions(this,
                                ofm->buffer_id,
                                buffer,
                                &skb_key,
                                ofm->actions,
                                actions_len,
                                false);
            ofpbuf_delete(buffer);
        }
        else
        {
            return -ESRCH;
        }
    }
    return 0;
}

int
OpenFlowSwitchNetDevice::ReceiveFlow(const void* msg)
{
    NS_LOG_FUNCTION_NOARGS();
    const ofp_flow_mod* ofm = (ofp_flow_mod*)msg;
    uint16_t command = ntohs(ofm->command);

    if (command == OFPFC_ADD)
    {
        return AddFlow(ofm);
    }
    else if ((command == OFPFC_MODIFY) || (command == OFPFC_MODIFY_STRICT))
    {
        return ModFlow(ofm);
    }
    else if (command == OFPFC_DELETE)
    {
        sw_flow_key key;
        flow_extract_match(&key, &ofm->match);
        return chain_delete(m_chain, &key, ofm->out_port, 0, 0) ? 0 : -ESRCH;
    }
    else if (command == OFPFC_DELETE_STRICT)
    {
        sw_flow_key key;
        uint16_t priority;
        flow_extract_match(&key, &ofm->match);
        priority = key.wildcards ? ntohs(ofm->priority) : -1;
        return chain_delete(m_chain, &key, ofm->out_port, priority, 1) ? 0 : -ESRCH;
    }
    else
    {
        return -ENODEV;
    }
}

int
OpenFlowSwitchNetDevice::StatsDump(ofi::StatsDumpCallback* cb)
{
    ofp_stats_reply* osr;
    ofpbuf* buffer;
    int err;

    if (cb->done)
    {
        return 0;
    }

    osr = (ofp_stats_reply*)MakeOpenflowReply(sizeof *osr, OFPT_STATS_REPLY, &buffer);
    osr->type = htons(cb->s->type);
    osr->flags = 0;

    err = cb->s->DoDump(this, cb->state, buffer);
    if (err >= 0)
    {
        if (err == 0)
        {
            cb->done = true;
        }
        else
        {
            // Buffer might have been reallocated, so find our data again.
            osr = (ofp_stats_reply*)ofpbuf_at_assert(buffer, 0, sizeof *osr);
            osr->flags = ntohs(OFPSF_REPLY_MORE);
        }

        int err2 = SendOpenflowBuffer(buffer);
        if (err2)
        {
            err = err2;
        }
    }

    return err;
}

void
OpenFlowSwitchNetDevice::StatsDone(ofi::StatsDumpCallback* cb)
{
    if (cb)
    {
        cb->s->DoCleanup(cb->state);
        free(cb->s);
        free(cb);
    }
}

int
OpenFlowSwitchNetDevice::ReceiveStatsRequest(const void* oh)
{
    const ofp_stats_request* rq = (ofp_stats_request*)oh;
    size_t rq_len = ntohs(rq->header.length);
    int type = ntohs(rq->type);
    int body_len = rq_len - offsetof(ofp_stats_request, body);
    ofi::Stats* st = new ofi::Stats((ofp_stats_types)type, (unsigned)body_len);

    if (!st)
    {
        return -EINVAL;
    }

    ofi::StatsDumpCallback cb;
    cb.done = false;
    cb.rq = (ofp_stats_request*)xmemdup(rq, rq_len);
    cb.s = st;
    cb.state = nullptr;
    cb.swtch = this;

    if (cb.s)
    {
        int err = cb.s->DoInit(rq->body, body_len, &cb.state);
        if (err)
        {
            NS_LOG_WARN("failed initialization of stats request type " << type << ": "
                                                                       << strerror(-err));
            free(cb.rq);
            return err;
        }
    }

    if (m_controller)
    {
        m_controller->StartDump(&cb);
    }
    else
    {
        NS_LOG_ERROR(
            "Switch needs to be registered to a controller in order to start the stats reply.");
    }

    return 0;
}

int
OpenFlowSwitchNetDevice::ReceiveEchoRequest(const void* oh)
{
    return SendOpenflowBuffer(make_echo_reply((ofp_header*)oh));
}

int
OpenFlowSwitchNetDevice::ReceiveEchoReply(const void* oh)
{
    return 0;
}

int
OpenFlowSwitchNetDevice::ForwardControlInput(const void* msg, size_t length)
{
    // Check encapsulated length.
    ofp_header* oh = (ofp_header*)msg;
    if (ntohs(oh->length) > length)
    {
        return -EINVAL;
    }
    assert(oh->version == OFP_VERSION);

    int error = 0;

    // Figure out how to handle it.
    switch (oh->type)
    {
    case OFPT_FEATURES_REQUEST:
        error = length < sizeof(ofp_header) ? -EFAULT : ReceiveFeaturesRequest(msg);
        break;
    case OFPT_GET_CONFIG_REQUEST:
        error = length < sizeof(ofp_header) ? -EFAULT : ReceiveGetConfigRequest(msg);
        break;
    case OFPT_SET_CONFIG:
        error = length < sizeof(ofp_switch_config) ? -EFAULT : ReceiveSetConfig(msg);
        break;
    case OFPT_PACKET_OUT:
        error = length < sizeof(ofp_packet_out) ? -EFAULT : ReceivePacketOut(msg);
        break;
    case OFPT_FLOW_MOD:
        error = length < sizeof(ofp_flow_mod) ? -EFAULT : ReceiveFlow(msg);
        break;
    case OFPT_PORT_MOD:
        error = length < sizeof(ofp_port_mod) ? -EFAULT : ReceivePortMod(msg);
        break;
    case OFPT_STATS_REQUEST:
        error = length < sizeof(ofp_stats_request) ? -EFAULT : ReceiveStatsRequest(msg);
        break;
    case OFPT_ECHO_REQUEST:
        error = length < sizeof(ofp_header) ? -EFAULT : ReceiveEchoRequest(msg);
        break;
    case OFPT_ECHO_REPLY:
        error = length < sizeof(ofp_header) ? -EFAULT : ReceiveEchoReply(msg);
        break;
    case OFPT_VPORT_MOD:
        error = length < sizeof(ofp_vport_mod) ? -EFAULT : ReceiveVPortMod(msg);
        break;
    case OFPT_VPORT_TABLE_FEATURES_REQUEST:
        error = length < sizeof(ofp_header) ? -EFAULT : ReceiveVPortTableFeaturesRequest(msg);
        break;
    default:
        SendErrorMsg((ofp_error_type)OFPET_BAD_REQUEST,
                     (ofp_bad_request_code)OFPBRC_BAD_TYPE,
                     msg,
                     length);
        error = -EINVAL;
    }

    if (msg)
    {
        free((ofpbuf*)msg);
    }
    return error;
}

sw_chain*
OpenFlowSwitchNetDevice::GetChain()
{
    return m_chain;
}

uint32_t
OpenFlowSwitchNetDevice::GetNSwitchPorts() const
{
    NS_LOG_FUNCTION_NOARGS();
    return m_ports.size();
}

ofi::Port
OpenFlowSwitchNetDevice::GetSwitchPort(uint32_t n) const
{
    NS_LOG_FUNCTION_NOARGS();
    return m_ports[n];
}

int
OpenFlowSwitchNetDevice::GetSwitchPortIndex(ofi::Port p)
{
    for (size_t i = 0; i < m_ports.size(); i++)
    {
        if (m_ports[i].netdev == p.netdev)
        {
            return i;
        }
    }
    return -1;
}

vport_table_t
OpenFlowSwitchNetDevice::GetVPortTable()
{
    return m_vportTable;
}

} // namespace ns3

#endif // NS3_OPENFLOW
